How consistent is the advice from stock assessments? Empirical estimates of inter‐assessment bias and uncertainty for marine fish and invertebrate stocks

Fishery management frequently involves precautionary buffering for scientific uncertainty. For example, a precautionary buffer that scales with scientific uncertainty is used to calculate the acceptable biological catch downward from the overfishing limit in the US federal fishery management system....

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Bibliographic Details
Published in:Fish and fisheries (Oxford, England) England), 2023-01, Vol.24 (1), p.126-141
Main Authors: Bi, Rujia, Collier, Chip, Mann, Roger, Mills, Katherine E., Saba, Vincent, Wiedenmann, John, Jensen, Olaf P.
Format: Article
Language:English
Subjects:
annual catch limits
Assessments
Bayesian analysis
Bias
Biomass
Buffers
Coefficient of variation
Coefficients
Empirical analysis
Estimates
Extreme values
Fish
Fisheries
Fisheries management
Fishery management
Fishing
Fishing mortality
Invertebrates
Marine fish
Marine fishes
Marine invertebrates
Mathematical models
Mortality
Overfishing
Pelagic fisheries
probability of overfishing
Probability theory
scientific uncertainty
Stock assessment
stock assessment consistency
Stocks
Uncertainty
Variation
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Summary:Fishery management frequently involves precautionary buffering for scientific uncertainty. For example, a precautionary buffer that scales with scientific uncertainty is used to calculate the acceptable biological catch downward from the overfishing limit in the US federal fishery management system. However, there is little empirical guidance to suggest how large buffers for scientific uncertainty should be. One important component of uncertainty is variation among different assessments of the same stock in estimates of management‐relevant quantities. We analysed commercially exploited marine fish and invertebrate stocks around the world and developed Bayesian hierarchical models to quantify inter‐assessment variation in terminal year biomass and fishing mortality estimates, reference points, relative biomass and fishing mortality estimates, and overfishing limits. There was little evidence of inter‐assessment bias; stock assessment estimates in the terminal year of the assessment were not consistently higher or lower than estimates of the same quantities in future years. However, there was a tendency for extreme values from the terminal year to be pulled closer to the mean in future years. Inter‐assessment variation in all estimates differed across regions, and a longer inter‐assessment interval generally resulted in greater variation. Inter‐assessment uncertainty was greatest for estimates of the overfishing limit, with coefficients of variation ranging from 17% in Europe (non‐EU) to 107% for Pacific Ocean pelagic stocks. Because inter‐assessment variation is only one component of scientific uncertainty, we suggest that these uncertainty estimates may provide a basis for determining the minimum size of precautionary buffers.
ISSN:1467-2960
1467-2979
DOI:10.1111/faf.12714